EP2734465A1 - Component having a fastening apparatus for add-on parts - Google Patents

Abstract

The invention relates to a component (5') of an escalator (1), of a moving walkway or of an elevator, which component (5') has a fastening apparatus (18) which comprises a spring element (20), a locking position (30) for locking the spring element (20) and a support position (31) for supporting an add-on part (7") to be fastened. The spring element (20) is arranged pivotably on the component (5'), wherein, in a tensioned state, the spring element (20) is locked in the locking position (30), and the add-on part (7") is pressed against the support position (31) by the tensioned spring element (20).

Description

 Component with a fastening device for attachments

description

The invention generally relates to an escalator, a moving walk or an elevator. The invention particularly relates to a component which has a fastening device which includes a spring element, a latching point for latching the spring element and a support point for supporting an attachment to be fastened.

Elevator systems have guide rails which are arranged in the elevator shaft and serve to guide a lift cage movably arranged elevator car and a counterweight. The guide rails are either arranged on a shaft scaffold or connected by means of a wall bracket with the (concrete) shaft wall. The guide rails are usually clamped by means of clamping claws on the wall brackets.

EP 1 679 280 describes an escalator which has two load-bearing side walls or half-timbered walls which are connected to one another by means of transverse struts. On the side walls track rails are arranged. These track rails serve to guide a step chain, which is arranged between a first deflection region and a second deflection region. Accordingly, the step band of the escalator on a flow and a return, with two track rails for the flow and for the return are provided. The track rails are firmly connected by means of several spring clips with the side walls. The attachment of the track rails on the side walls or cross struts by means of spring clips is compared to welding or screwing these components a considerable simplification of the assembly and has proven itself in practice.

A disadvantage of the fastening device with spring clips disclosed in EP 1 679 280 is that the spring constant of the spring clips is relatively high in order to achieve a high clamping force and thereby a secure connection of the track rails to the side walls. These spring clips are therefore only with considerable effort, for example, with a blow of a hammer mountable. The use of an assembly tool, such as a hammer but can cause plastic deformation on the spring clip, which can lead to a partial loss of its clamping force. Furthermore, the parts to be joined must be made very precise because even small differences in the spring travel or deflection in the clamped state can lead to large differences in the existing clamping force in the individual joints due to the high spring constant of the spring clip. In order to enable the mounting of raceways and track rails by means of the known spring clips, these tracks and track rails in the form of elaborately designed and costly in production hollow sections are required.

Object of the present invention is therefore to provide a component with a fastening device that overcomes the disadvantages listed above. This object is achieved by a component of an escalator, a moving walk or a lift, this component has a fastening device which includes a spring element, a locking point for engaging the spring element and a support point for supporting an attachment to be attached. In the described embodiments, the spring element is pivotally mounted on the component, wherein in a tensioned state, the spring element is engaged in the latching and the attachment is pressed by the tensioned spring element against the support point.

The fastening device described here allows easy installation, but also a quick dismantling of the attachments by hand without a tool must be used. This is a decisive advantage not only in the manufacture of an escalator or moving walk, but also in their installation in a building and during maintenance work. Worn attachments such as raceways, rails and guide rails can be replaced due to the fastening device within a short time, for example, a few hours. Furthermore, a high clamping force can be generated on the attachment, even if the spring element has a substantially smaller spring constant than the spring clip known from the prior art. These advantages are made possible by the pivotal arrangement of the spring element on the component. The pivot axis of the spring element acts as a lever bearing of the spring element and the spring element itself as a clamping lever.

In a first embodiment of the fastening device, the spring element has a Bearing point through which the spring element is pivotally mounted on the component. Further, the spring element includes a clamping point and a lever end, wherein between the bearing point and the clamping point a short lever arm and between the clamping point and the lever end, a long lever arm is arranged. When clamped spring element, the attachment between the support point and the clamping point is arranged. Depending on the selected gear ratio between the short lever arm and the long lever arm can be at a given clamping force with more or less force the spring element engage in the locking position. By using a spring element as a clamping lever, the fastening device is extremely insensitive to tolerance differences of the component, the spring element and the attachment. Even larger deviations in the manufacturing dimensions of two fastening devices result in only slight differences in the force acting on the attachment clamping force.

In a second embodiment of the fastening device, the spring element is mirror-symmetrical to its longitudinal extension and has a bearing point, through which the spring element is pivotally mounted on the component. Furthermore, the spring element by the mirror-symmetrical design includes two spring legs, each spring leg has a clamping point and a lever end. Between the bearing and each clamping point a short lever arm and between the clamping points and the lever ends are each arranged a long lever arm. When clamped spring element, the component between the spring legs and the attachment between the support point and the clamping points are arranged.

The second embodiment has all the advantages of the first embodiment. The second embodiment further has the additional advantages that the spring element is trapped by the component in the orthogonal direction to the clamping force and therefore is insensitive to lateral forces that can act on the spring element. Accordingly, this embodiment has an even higher stability and safety against unintentional release, as the first embodiment.

The spring element can be machined in one piece from the component. However, this one-piece design can limit the freedom of design, since the component is usually made of a structural steel, for example S235JR + AR (tensile strength 360 N / mm ² according to EN 10025-2: 2004-10). This structural steel has a lower tensile strength as spring steel, for example 38Si7, which has a tensile strength of 1300-1600 N / mm ² . Preferably, therefore, the component and the spring element are designed as separate parts, wherein the component made of structural steel and the spring element is made of spring steel.

The clamping point of the spring element can be formed by an easy-to-produce, angled fold. This has the advantage that the clamping point has a rounding, which is directed against the attachment and during clamping allows a relative movement between the surface of the attachment and the clamping point of the spring element. Furthermore, given by the angular bending of the force application point of the clamping force on the attachment sufficiently accurate.

In order to facilitate the assembly and tensioning of the spring element, the long lever arm at least twice the length of the short lever arm.

The fastening device can be used in many places within an escalator or moving walks for connecting components. For example, the component can be a truss formed from supporting side walls and cross struts or supporting structure of an escalator or moving walk and the attachment be a frame or a module of an escalator or moving walk. The bulkhead is usually a flat, projecting from the structure against the inside of the structure projecting component referred to which add-on parts such as track rails, guide rails and raceways can be arranged. Furthermore, they usually also serve the stiffening of the structure, in particular with respect to its torsional rigidity.

Modules are sections of the escalator or moving walkway. These can be designed differently according to their function. For example, a first module may have a deflection region of the step chain, a second module may include the drive and deflection region of the step chain, and further identical intermediate modules with side walls and cross struts may be present. An intermediate module may also comprise a plurality of frames which are connected to each other by track rails, rails and / or guide rails, wherein one or more intermediate modules can be inserted into an existing supporting structure. By joining two or more modules, the two deflection areas the step chain are interconnected.

The bulkhead or the module of an escalator or moving walk can now in turn have fastening devices for additional attachments themselves. Thus, the bulkhead or the module is the component and the attachment is a track rail, track rail or guide rail.

The fastening device can also be used in elevator construction. The component can be, for example, a wall mount arranged in an elevator shaft or a shaft frame arranged in the elevator shaft. With the wall bracket or the shaft frame can be connected as attachments a running track of an elevator car and / or a balance weight by means of fastening devices.

The locking point can be designed in various ways. In a first embodiment, the latching point can be molded onto the component. In a further embodiment, the latching point can have an insert part, which can be fastened to the component. Preferably, the insert and the component by projections, for example in the form of hooks, and recesses designed such that the insert is fixed by this and by means of the bearing force of the spring leg on the component. Furthermore, by means of differently shaped inserts, the clamping force of the spring element can be adapted to the conditions of use.

To facilitate the engagement of the spring element to exciting, an expanding wedge may be formed at the locking point. This can be formed on the component, but also on the insert.

The latching point can have certain properties that influence the operating behavior of the escalator, the moving walk or the elevator. For example, the insert can be made of plastic, so that vibrations dampened and thereby operating noise can be reduced. Of course, the locking point may also have differently designed damping elements. Thus, plastic inserts are conceivable, which are arranged in the contact region between the spring element and the locking point. Since the clamping force of the spring element acts only in one direction, the support point preferably has at least one stop point for limiting at least one direction of movement of the attachment. The stops not only limit one or more directions of movement of the attachment relative to the component, but can also serve as mounting aids. For example, a running rail can be inserted into the support points of the ribs, wherein the stop points prevents slipping of the running rail from the support points.

The support point may also have a sliding surface. This is particularly important for guide rails of a hoistway. Buildings made of concrete can show considerable shrinkage over time, which leads to a shortening of the elevator shaft length. Accordingly, the distances between the wall brackets in the elevator shaft also change. The steel guide rails do not exhibit this shrinkage. If no relative movement parallel to the longitudinal extent of the elevator shaft would be possible between the wall brackets and the guide rail, the guide rail or the wall brackets would be deformed or even destroyed. The same can also happen by temperature fluctuations in the elevator shaft, since concrete and steel have different thermal expansion coefficients.

The sliding surface may be a smooth surface of the support point, but also a plastic intermediate layer, which can be arranged between the support point and the attachment. In the case of a plastic intermediate layer, however, the permissible surface pressure of the material must be observed, so that the clamping force of the spring element is not unduly reduced due to creep. Furthermore, construction-related dimensional deviations can be compensated by the plastic liners, with a set of different thickness plastic liners is required. The plastic liners may have the form of a sliding shoe or a sliding insert.

The support can also have anti-slip agents. These can be used in particular for escalators and moving walks, since there is the environment of the track rails, the tracks or the guide rails usually also made of steel and a rigid connection of these attachments with the components such as frames, cross struts and side panels is desired. As anti-slip agents, for example Tooth profiles or profiles with sharp points to be formed at the support point, the teeth of which penetrate due to the clamping force of the spring element in the resting surface of the sub-component. Furthermore, it is also possible to use rough surfaces such as, for example, applied to the support surface, abrasive coatings.

The attachment device is preferably designed such that the reaction force of the external forces acting on the attachment is directed in the same direction as the clamping force of the spring element acting on the attachment. As a result, the external forces do not act against the clamping force and it can never come to overcoming the clamping force. A lifting of the attachment from the support point can thus be prevented.

The component of an escalator, a moving walkway or a lift with a fastening device will be explained in more detail below by way of examples and with reference to the drawings. Show:

Figure 1: a schematic representation of an escalator with track rails and with a step band;

Figure 2 is a section through the escalator taken along the line A-A of Figure 1, with ribs as a carrier of the track rails;

Figure 3: a three-dimensional view of an embodiment of a fastening device which removably connects a frame with a framework or structure;

Figure 4: in three-dimensional view a shown in Figure 2 Spant with raceways, rails and guide rails, the raceways and rails are attached to the frame with fastening devices;

Figure 5: in elevation of the frame shown in Figure 4 with raceways, rails and guide rails;

6: in elevation and in a larger illustration, the marked in the figure 5 cut B with a first embodiment of the support point;

FIG. 7A: a second embodiment of the contact point formed on the component in a sectional elevation;

FIG. 7B shows a sectional view of a third possible embodiment of the contact point formed on the component;

FIG. 8 shows the latching point formed on the component in a three-dimensional view, and illustrated in FIGS. 4 to 6

Figure 9: a guide rail of a lift in three-dimensional view, which is arranged in an elevator shaft, not shown.

Figure 1 and Figure 2 show an escalator 1 with a handrail 2.1 bearing balustrade 2 and between base plates 3 laterally guided steps 4. The escalator 1 connects a first floor El with a second floor E2. Casters 4.1 of the stages 4 travel on track rails 6.3 ", 6.4", or on raceways 6.1 ", 6.2", which are fastened to the frames 7 with the fastening devices 8. Furthermore, two guide rails 6.5 are fixed to the frame 7 with a fastening device 8. These fastening devices 8 are described in more detail below with reference to Figures 3 to 9. Each bulkhead 7 is connected to a framework 5 of the escalator 1, for example by means of a screw connection, welded connection, press connection, riveted connection or by clinching (clinching).

As shown in a three-dimensional representation in FIG. 3, the frame can also be connected to the truss as component 5 'by means of a fastening device 18. Since the fastening device 18 can be quickly detached, this type of attachment fixes the frames as attachments 7 "on the truss is an invaluable advantage if the escalator or moving walkways have to be equipped with new raceways and / or frames due to age.

The fastening device 18 has a spring element 20 with two spring legs 20.1, 20.2 and a bearing point 22. Each spring leg 20.1, 20.2 has a clamping point 23 and a lever end 24. Between the bearing point 22 and the clamping points 23 are each a short lever arm 25 and between the clamping points 23 and the lever ends 24 each have a long lever arm 26 is arranged. The spring element 20 is mirror-symmetrical to its longitudinal extension, wherein the mirror plane between the two spring legs 20.1, 20.2 and orthogonal to the pivot axis 27 of the bearing 22 is arranged.

The locking device 30 shown in Figure 3 has two integrally formed on the component 5 'bracket 30.1, 30.2, wherein each one bracket 30.1, 30.2 each a long lever arm 26 receives when the spring element 20 is tensioned.

The attachment of the attachment 7 "on the component 5 'is extremely simple First, the spring element 20 or its bearing point 22 is inserted into the bearing receptacle 32, in such a way that the component 5' between the two spring legs 20.1, 20.2 is arranged However, long lever arms 26 may not yet be engaged in the latching point 30. The two spring legs 20.1, 20.2 are to be brought into a starting position 38, so that the attachment 7 "can be inserted into the support point 31. Subsequently, the attachment 7 "is inserted and aligned in the support point 31. The two spring legs 20.1, 20.2 can now be pivoted, lifted over the brackets 30.1, 30.2 and latched under the brackets 30.1, 30.2 around the pivot axis 27 are the clamping points 23 on the attachment 7 "and press it against the support point 31, even before the spring legs 20.1, 20.2 reach the locking point 30. Due to the leverage of the short lever arm 25 and the long lever arm 26, despite manual assembly, a very high, on the attachment 7 "acting clamping force or biasing force can be generated.

FIG. 4 shows a single bulkhead from FIG. 2 with mounted rails, raceways and guide rails in a three-dimensional representation. The bulkhead thus becomes the component 7 ', the running rails for attachments 6.1 ", 6.2", the raceways for attachments 6.3 ", 6.4" and the guide rail also become an attachment 6.5 " 41 of the fastening device 18 shown in Figure 3, which is why identical Features the same reference numerals are used. The latching point 41 of the spring element 20 is shown in FIG. 8 and will be described in detail below.

On the component 7 'are also made of thin sheet metal guide rails 9.1, 9.2 arranged. These limit a possible lifting of the rollers not shown or stepped rollers of the attachment parts 6.1 ", 6.2". The U-shaped guide rails 9.1, 9.2 can be spread apart transversely to the longitudinal he stretching due to the small thickness and can be engaged without much effort in dovetail 10 feet, which is formed on the component 7 '. Of course, the guide rail 9.1, 9.2 can also be fixed by means of a fastening device 8 on the component T.

5 shows in elevation the bulkhead or the component 7 'with the raceways, rails and guide rails as attachment parts 6.1 ", 6.2", 6.3 "6.4", 6.5 "shown in FIG 4. In this view, the fastening devices 8 are braced with the braces Spring elements 20 are much better visible .. The example of an attachment 6.1 (track) and the active lever lengths Ii, 1 ₂ are shown .. Due to the angular fold 29 of the spring element 20 and the arrangement of the spring element 20 on the component 7 ', these are shorter than the associated lever arms 25, 26. The operating lever length I2 of the long lever arm 26 is, of course, dependent on the direction of the manual force F _{H to be} engaged, the operative lever length of the short lever arm 25 only changes slightly if the angled fold 29 or the clamping point 23 formed thereby is due to of manufacturing tolerances has a position deviating from the design position e is the theoretical position of the spring element 20 to understand in the clamped state, when all dimensions of the spring element 20, the component T and the attachment 6.1 "are considered without tolerance deviations. Of course, the clamping point 23 must never exceed the dead center, that is, the active lever length Ii of the small lever 25 must never be less than 0. If the dead center is exceeded and thus the active lever length is less than 0, then the spring element 20 can not be tensioned, since the clamping point 23 with increasing pivot angle of the spring element 20 in the clockwise direction and relative to the component 7 ', from the attachment 6.1 " Fastening device 8 has a very high level of reliability due to the fact that a non-tensionable spring element 20 is recognized immediately during assembly and measures for remedying For example, the insertion of a sheet between the clamping point 23 and the attachment 6.1 "can be done immediately., Broken or deformed spring elements 20 are immediately recognized during inspections and / or maintenance due to lack of clamping force and can be replaced, the number of fastening devices 8 over the longitudinal extent an escalator, a moving walkway or a hoistway is to be chosen so that the reliability is ensured even in the event of failure of individual spring elements 20.

Furthermore, the advantageous positioning of the spring elements 20 with respect to the raceways and rails acting, external forces can be represented by means of Figure 5. The example of an attachment 6.2 "(track), the external force F _s, the clamping force F _{F of} the spring element 20 and caused by the external force F _s bending moment M _L and the support of the moment M _{L represented} by the reaction force F _R. Die Force F _s acts due to the mass and load to be carried on a step of the escalator or a pallet of a moving walk on the roller 4.1 on the attachment 6.2 ". This is supported by the component 7 ', due to the design of the rail support 7.1 a bending moment M _L in the component 7' is present and could be due to the bending moment M _L a small elastic deformation or a slight tilting of the rail support 7.1. This tilting is counteracted not only by the rail support 7.1, but also by the fold of the attachment 6.2 ", the contact point 31. This reaction force F _R acting on the support point 31 points in the same direction as the tension force F _{F of} the spring element 20. Further, transverse forces FQ also occur supported by the support point 31, which can also act through the rollers 4.1 on the attachment 6.2 ".

FIG. 6 shows, in a larger representation, the detail B marked in FIG. 5. This shows that two attachments 6.3 ", 6.4" can also be fastened to the component 7 'with a fastening device 8. Of course, three or more attachments with the mounting device 8 on the component T can be set. In particular, the insensitivity of the fastening device 8 with respect to large manufacturing tolerances comes into play here.

So that a relative movement in the direction of the longitudinal extension of the attachments 6.3 ", 6.4" between the component 7 'and the adjacent attachment 6.3 "can be prevented, For example, the contact point 51 of the component 7 'may have a suitable shape, for example a tooth profile 43. These can, for example, have a greater hardness than the material of the attachment 6.3 "When the spring element 20 is tensioned, the protruding teeth of the tooth profile 43 penetrate partially into the material of the attachment 6.3". This positive locking prevents any relative movement between the component 7 'and the attachment 6.3 "in a plane that extends orthogonally to the direction of the clamping force F _{F of} the spring element 20. Here, too, the immobility of the fastening device 8 proves to be an outstanding feature at different penetration depths Further, suitable tooth profiles 43 or profiles with sharp tips are of course also applicable, and instead of the tooth profile 43, a sliding-inhibiting coating, for example a flame-sprayed carbide hard coating or a slip-resistant or non-slip intermediate layer between the support 51, can be used and the attachment 6.3 "be arranged.

Also clearly visible are the abutment points 34, 35 arranged on the component 7 ', which restrict the directions of movement of the attachments 6.3 "6.4" in at least one direction.

Furthermore, the embodiment of the bearing receptacle 32 can be seen, which is formed in the component 7 '. This is preferably not designed as a bore, but as a slot-shaped recess. The open end of the bearing receptacle 32 preferably extends in the opposite direction to the bearing force F _{P of} the spring element 20. This embodiment allows for easy insertion of the spring element in the component 7 '.

FIG. 7A shows a further embodiment possibility of the support point 61 formed on the component T in a cutaway elevation. Here, a relative movement of the attachment 6.1 "in the direction of its longitudinal extension is desired." The attachment 6.1 "is mentioned only as an example, and the other attachments, not shown, can also be fixed to the component T by means of a suitably designed attachment device. A relative movement can be easily admitted, since the partially shown spring element 20 by the component T penetrating bearing point and the locking point (both not shown) is held stationary on the component 7 '. In order to support a possible relative movement is between the attachment 6.1 "and the support point 61 is a sliding shoe 52 arranged. This is made in the illustrated embodiment of a plastic with high strength and low creep, for example, a glass fiber reinforced plastic. The shoe 52 made of plastic also has vibration damping properties.

Of course, as shown in FIG. 7B, a sliding insert 53 can be arranged between the spring element 20 and the attachment 6.1 ", which improves the sliding properties and / or vibration damping properties between the attachment 6.1" and the clamping points 23 of the spring element 20. Furthermore, through the sliding insert

53, the clamping points 23 in the direction of the sliding movement X are supported against each other to avoid lateral drifting away.

FIG. 8 shows the latching point 41 formed on the component 7 'in a three-dimensional view. For reasons of clarity, the bearing mount formed on the component T has not been shown; instead, the entire spring element 20 and its bearing point 22 are visible. The latching point 41 has a hook formed on the component 7 '71 and an insert 72 with an opening 72.1. In the assembled state, the hook 71 extends through the opening 72.1. The insert 72 is further secured by the supporting forces F _{A of} the spring element 20 in the hook 71. The farther the insert 72 is located away from the bearing 22, the lower are the supporting forces F _A acting on the insert 72. The insert 72 may be made of metal, for example made of steel, but also made of plastic. An insert 72 made of plastic has the advantage that vibrations are damped within the mounting device, so that the operating noise of the escalator, the moving walk or the elevator can be minimized.

The insert 72 further has an expanding wedge 72.2, which is formed by two lateral chamfers. When tensioning the spring element 20 whose both spring legs 20.1, 20.2 of the dash-dotted lines indicated starting position Y in the two, formed on the insert 72 recesses 72.3, 72.4 must be engaged. The expanding wedge 72.2 facilitates the spreading apart of the two spring legs 20.1, 20.2, so that they can be easily lifted over the lugs 72.5, 72.6 of the insert 72 and snapped into the recesses 72.3, 72.4. Figure 9 shows a guide rail of a lift in three-dimensional view, which is arranged in an elevator shaft, not shown. At this guide rail, for example, the elevator car and / or the balance weight or counterweight is performed. The guide rail as an attachment 80 "is fastened to the shaft wall of the elevator shaft by means of a component 90. The component 90 'in turn has a fastening device 28. As in the exemplary embodiments described above, a contact point 91, a latching point 92 and a bearing receptacle 93. The latching point 92 is formed by means of an S-shaped fold of a region of the component 90 'delimited by two parallel cuts, in order to limit the freedom of movement of the mounting part 80 ", the component 90' further points a stop 94 on.

The spring element 95 shown differs from the spring elements of the embodiments shown above in that it has only one spring leg 95.1. The features such as a clamping point 95.9, a lever end 95.4, a bearing 95.2, a short lever 95.5 and a long lever arm 95.3 are also present in this spring element 95. Also, the operation and the assembly process of this fastening device 28 correspond to the preceding embodiments.

Although the invention has been described by way of illustrating specific embodiments, it will be apparent that numerous other embodiments can be provided with the knowledge of the present invention, for example by combining the features of the individual embodiments and / or interchanging individual functional units of the embodiments. For example, in all embodiments, the spring element have only one spring leg. Of course, in all embodiments, sliding shoes, sliding inserts, damping inserts, tooth profiles or profiles with sharp tips and the like more, can be used. It is also conceivable that an attachment, which is fixed to a plurality of components, is connected by differently configured fastening devices with the components. For example, one of the fastening devices may have a tooth profile and all other fastening devices have a sliding block. Accordingly, appropriately configured attachment devices are included within the scope of the present claims.

Claims

claims

1. component (5 ', 7', 90 ') of an escalator (1), a moving walk or a lift, which component (5', 7 ', 90') has a fastening device (8, 18, 28) which has a spring element (20, 95), a latching point (30, 41, 92) for latching the spring element (20, 95) and a support point (31, 51, 61, 91) for supporting an attachment (6.1 ", 6.2", 6.3 ", 6.4", 6.5 ", 7", 80 "), characterized in that the spring element (20, 95) on the component (5 ', 7', 90 ') is pivotally mounted, wherein in a tensioned state, the spring element (20, 95) in the latching point (30, 41, 92) is engaged and the attachment (6.1 ", 6.2", 6.3 ", 6.4", 6.5 ", 7", 80 ") by the tensioned spring element (20, 95 ) against the support point (31, 51, 61, 91) is pressed.

Second component (5 ', 7', 90 ') according to claim 1, wherein the spring element (95) has a bearing point (95.2) through which the spring element (95) on the component (5', 7 ', 90') pivotally is arranged and the spring element (95) further includes a clamping point (95.9) and a lever end (95.4), wherein between the bearing (95.2) and the clamping point (95.9) a short lever arm (95.5) and between the clamping point (95.9) and the Lever end (95.4) is a long lever arm (95.3) is arranged, and that when clamped spring element (95) the attachment (6.1 ", 6.2", 6.3 ", 6.4", 6.5 ", 7", 80 ") between the support point (31 , 51, 61, 91) and the clamping point (95.9) is arranged.

3. component (5 ', 7', 90 ') according to claim 1, wherein the spring element (20) is mirror-symmetrical to its longitudinal extension and a bearing point (22) through which the spring element (20) on the component (5', 7 ', 90') is pivotally mounted and the spring element (20) further includes two spring legs (20.1, 20.2), wherein each spring leg (20.1, 20.2) has a clamping point (23) and a lever end (24), between the bearing ( 22) and each clamping point (23) each have a short lever arm (25) and between the clamping points (23) and the lever ends (24) each have a long lever arm (26) is arranged, and wherein the component (5 ', 7', 90 ') between the spring legs (20.1, 20.2) and, in tensioned spring element (20), the attachment (6.1 ", 6.2", 6.3 ", 6.4", 6.5 ", 7", 80 ") between the support point (31, 51 , 61, 91) and the clamping points (23) is arranged.

4. component (5 ', 7', 90 ') according to claim 2 or 3, wherein the clamping point (23, 95.9) of the Spring element (20, 95) is formed by an angular fold.

5. component (5 ', 7', 90 ') according to one of claims 2 to 4, wherein the long lever arm (26, 95.3) at least twice the length of the short lever arm (25, 95.5).

6. component (5 ', 7', 90 ') according to one of claims 1 to 5, wherein the component (5', 7 ', 90') is a supporting structure (5 ') an escalator (1) or a moving walkway and the attachment (7 ") is a bulkhead or module of an escalator (1) or a moving walkway.

7. component (5 ', 7', 90 ') according to one of claims 1 to 6, wherein the component (5', 7 ', 90') a frame (7 ') or a module of an escalator (1) or a Moving walk is and the attachment (6.1 ", 6.2", 6.3 ", 6.4", 6.5 ") is a track rail, track rail or guide rail.

8. component (5 ', 7', 90 ') according to one of claims 1 to 5, wherein the component (90') is arranged in a hoistway wall bracket and the attachment (80 ") a running rail or guide rail of an elevator car and / / or a balance weight.

9. component (5 ', 7', 90 ') according to one of claims 1 to 8, wherein the latching point (30, 92) of the component (5', 7 ', 90') is integrally formed.

10. component (5 ', 7', 90 ') according to one of claims 1 to 9, wherein the latching point (41) has an insert (72).

11. component (5 ', 7', 90 ') according to one of claims 1 to 10, wherein at the latching point (41) an expanding wedge (72.2) is formed.

12. component (5 ', 7', 90 ') according to one of claims 1 to 11, wherein the latching point (41) has a damping element.

13. component (5 ', 7', 90 ') according to one of claims 1 to 12, wherein the support point (31, 51, 61, 91) at least one stop point (34, 35, 94) for limiting a direction of movement of the attachment ( 6.1 ", 6.2", 6.3 ", 6.4", 6.5 ", 7", 80 ").

14. component (5 ', 7', 90 ') according to one of claims 1 to 13, wherein the support point (31, 61, 91) has a sliding surface, a sliding insert (53) or a sliding shoe (52).

15. component (5 ', 7', 90 ') according to one of claims 1 to 13, wherein the support point (31,

51, 91) has anti-slip agents.

16, component (5 ', 7', 90 ') according to any one of claims 1 to 15, wherein the reaction force (F _R ) acting on the attachment, external forces (F _s , FQ) in the same direction as that on the attachment acting clamping force (F _F ) of the spring element (20, 95) is directed.